Method of making a low-profile crystal package with an improved crystal-mounting arrangement

ABSTRACT

A low-profile crystal package wherein the wire bonding operation from the electrode pattern of the crystal plate to the terminal posts may be accomplished without fear of fracture of the crystal plate itself. The crystal blank is positioned on a support member which in turn initially sits on a ring of indium. In this position, the crystal blank is not in contact with the split center support post whose top surface is covered with indium paste, and is supported around its periphery during wire bonding. When all the wire bonding operations are effectuated, the assembly is subjected to sufficient heat wherein the indium material will melt, which will cause the support member to be drawn downward, thereby resulting in the crystal plate being supported and fastened only by the center supports, with the periphery of the crystal plate being free to vibrate with no extraneous dampened support.

This is a division of application Ser. No. 377,289, filed May 12, 1982, now U.S. Pat. No. 4,453,104.

BACKGROUND OF THE INVENTION

The present invention relates in general to crystal mounting arrangements for quartz crystal packages and more particularly to a low-profile crystal package with an improved crystal mounting arrangement which facilitates multiple electrical connections to each surface of the crystal plate without flexing or repositioning the crystal plate.

It has long been the practice to hermetically seal the protective metal crystal package. Once sealed, the crystal package can be used in many different environments with a high degree of relative confidence that the internal crystal plate will perform at the desired frequency.

In recent years, space limitations have required smaller and smaller crystal mounting assemblies, which has caused an increase in the electrical and mechanical problems relative to adequately fixturing a crystal plate within a crystal package, while not causing damage to the crystal plate, maintaining frequency standardization and avoiding internal environment contamination during the sealing process. Likewise, as crystal applications have become more and more complex, more electrical contact points are required, on smaller and smaller crystal plates. Thus, it has been the prior-art practice to provide a small crystal package which allows the mounting of the crystal plate within a metal evacuated container, such container having terminal pins projecting within the internal cavity which are connected via wire leads to the electrodes found on the crystal plate. These same terminal pins also serve to support the unit within the evacuated cavity as its seams are sealed either by soldering, hot-welding, or cold-welding technologies.

The use of high-pressure cold-welding technology has found favor in the prior art since it has the primary advantage of being free from fumes and contamination; due to the pressures involved, it has an occasional disadvantage of causing distortion to the metal container during the welding operation, which may result in the internal terminal pins being displaced from their intended positions. Since the crystal plate is secured by the terminal pins, will cause a stress force to be applied to the crystal plate, which will have negative consequences to the frequency characteristics of the crystal plate. The present invention is concerned with a crystal package that is preferably hermetically sealed by the utilization of cold welding apparatus, but is not limited to solely the cold welding technological art.

In the prior art there are various types of crystal mounting apparatus which are in common usage. In one approach, the quartz crystal wafer is supported by the center mounting post, which allows the horizontal mounting of the crystal and reduces the overall height of the crystal package assembly. A disadvantage of this crystal mounting approach is that the crystal plate needs to be adequately supported during the wire bonding process so as to withstand the surface pressures involved without sustaining damage to the crystal plate. During assembly of the crystal wafer onto its respective center post mounting position, it is desirable to avoid overstressing the wafer. Such stresses can occur by the means which are used to mount the crystal wafer in the crystal package or by the mechanical stresses which develop during the hermetic sealing of the crystal package itself.

The prior art sealing techniques have generally consisted of the steps of hermetically sealing a pair of terminals in an eyelet to form a header, mounting a crystal wafer on an associated header, and hermetically sealing the header to a metal or glass container, with the crystal wafer positioned within such container. Headers have been characterized either as matched glass or compression glass headers. In a glass header, a single vitreous material is used to fabricate the terminals and eyelets, while a second vitreous material which has the same thermal co-efficient of expansion as the eyelet and terminals is used to seal the terminals to the eyelet. Generally, the eyelet and terminals are made of an iron-nickel-cobalt alloy material such as KOVAR and the vitreous material is a glass which has been selected to have a thermal co-efficient expansion substantially the same as that of KOVAR. The sealing process is facilitated by placing molten glass in the eyelet around the terminals and then cooling the glass to cause it to shrink and tightly grip the terminals. The similar coefficients of thermal expansion of the KOVAR components and the vitreous material insure that the seal between the terminals and the eyelet will be maintained. In both the matched and the compression glass headers the integrity of the terminal to eyelet seal depends upon the attainment of a good seal between the terminal and the glass.

A disadvantage common to all of the prior-art devices is the relatively high cost and complexity which exists for the various crystal package apparatus.

SUMMARY OF THE INVENTION

It is therefore an object of the present invention to provide an improved five-spot cold-welded crystal package wherein the forgoing deficiencies found in the prior art are overcome.

Another object of this invention is to provide an improved low-profile crystal package containing a crystal mounting arrangement which will allow the internal crystal wafer to be placed on a flat surface of an internal support member will allow the wire bonding to a plurality of internal header pins without repositioning the crystal plate for additional assembly operations.

Still another object of the invention is to provide an improved crystal package which is hermetically sealed and which will accommodate an associated crystal plate, having a top-and bottom-electrode pattern, to be wire-bonded to the associated connecting header pins in such a manner as not to flex the crystal plate, once positioned on the flat surface of internal support members.

A further object of this invention is to provide the crystal plate with a stationary and temporary support while wire bonding is effectuated, and then allow the support member to automatically cease being a support member to the crystal plate without flexing or repositioning the crystal plate located within the support member.

A further object of the present invention is to improve the center-mount method of crystal mountings by allowing a crystal plate to be firmly supported and protected during the wire bonding of the multiple spot electrode pattern to the appropriate header terminal pins either by manual or automated wire bonding processes without damaging the crystal plate.

Yet another objects of the present invention is to provide a five-spot cold-welded crystal package which is of low cost, of simple design and can be readily and easily manufactured.

In practicing the invention, a method of stationing a crystal plate within a low profile package assembly is provided for accommodating a horizontally mounted crystal plate, with an associated electrode pattern on each top and bottom surface, in such a manner as to provide support and protection to the crystal plate during the wire-bonding manufacturing step. A split mounting post is centrally located within the glass header base member, said header base member having a plurality of locating pins and a specified number of terminal connecting pins. A circular ring of conductive material, which is of a predetermined size and of a material conducive to melting, is centrally positioned on the top surface of the glass header base, in such a manner as to encircle the center split mounting post. An elongated support member, with an inner centrally located recessed cavity and aperture, is positioned atop the circular ring. This elongated support member positions itself over the two locating pins located on the glass header base member. The crystal plate with its conductive electrode areas formed on each surface thereof, is located within the flat recessed cavity of said support member, said plate being supported around its total peripheral edge. Conventional wire bonds are made between the contact pads on the crystal plate and the correct terminal pins of the glass header base member. Pressure is then applied, via the use of a weighted fixture or other appropriate means, to the top surface of the support member which is heated to the melting point of the conductive material. This will cause the circular ring to melt and the ring to experience a decrease in overall thickness. The melted conductive material will fuse to the top of the glass header base member, resulting in the crystal plate being suspended and mounted atop the center split ground post. A protective overfitting metal cover is then hermetically sealed to the glass header base member through the use of cold welding apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS

The features of the present invention which are believed to be novel are set forth with particularity in the claims. The invention itself, however, together with further objects and advantages thereof, may be best understood by reference to the following description when taken into conjunction with the accompanying drawings, in which like reference numerals refer to like elements in several figures, and in which:

FIG. 1 is an exploded view of a crystal package assembly, constructed in accordance with the present invention.

FIG. 2 is a top plan view of the assembly according to the invention illustrating the crystal plate positioned on the header base member, after wire bonding the contact pads of the crystal plate to the appropriate terminal pins has been facilitated.

FIG. 3 is a cross-sectional view along the lines 3--3 of FIG. 2 showing the support member in a position prior to the indium ring being melted.

FIG. 4 is a sectional side view along line 3--3 of FIG. 2 illustrating the lowered position of the support member after the melting of the Indium ring and after the cold-welding process has sealed the outer metallic cover to the internal header base.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring now to the drawings, FIG. 1 shows an exploded view of the individual elements comprising the crystal package assembly 10, which has been constructed in accordance with the present invention. A glass header assembly 30 consists of two locating pins 32A and 32B, five terminal connecting pins 34, and a center split mounting post 38. The plurality of terminal connecting pins 34 need to be of a electrically conductive material, one of which is KOVAR, but is not limited to this particular commercially suitable material. The bottom of the exposed center mounting post and the bottom of the five connecting pins are flush with the bottom surface of the glass header (not shown). The center split mounting post 38 protrudes above the glass header and has two independent sides, 36A and 36B. A ring of indium 42, or other conductive and meltable material, is placed on the glass header, over which is placed a support member 44. The support member 44 has a recessed center cavity 45 and two female apertures 48A and 48B which accomodate the locating pins 32A and 32B. The associated crystal plate 46 has electrode patterns represented at 47, on its top and bottom surfaces and is dimensioned to fit within the cavity 45 of the support member 44. This is accomplished in a manner to enable the crystal plate 46 to be placed on a flat surface within the cavity 45. In this position, the crystal blank 46 is not in contact with the center mounting post 38 and is supported around its periphery by the recessed cavity 45 of the support member 44 during the wire bonding process. A small amount of Indium paste is placed atop the center mounting post 38 (not shown). The crystal plate 46 is then wire bonded, utilizing associated wire bonding pads 35, which are located on the top surface of the crystal plate 46, to the five terminal connecting pins 34, which connect to the appropriate electrode patterns 47 (connection not shown). Pressure is applied by suitable means such as a weighted fixture (not shown) to the top support member 44 and the entire glass header assembly is heated to 157° C., the melting point of indium. As the indium ring 42 melts, its thickness will decrease and it will it will fuse to the top of the header 30, thereby pulling the support member 44 down, that the edge of the crystal plate 46 is no longer supported by the support member 44. The melted indium material will wick into the surrounding recessed areas around the center split ground post 38, forming a semi-seal between the glass header and the center split ground post. The crystal will then remain suspended only on the two independent ground sides 36A and 36B of the center mounting post 38, with the periphery of the crystal plate being free to vibrate with no extraneous dampened support. The protective metal cover 50 is snuggly over-fitted to the header assembly 30 in such a manner as to align edge 49 with header base member extending flange 31. The whole unit is thereafter cold-welded to hermetically seal the unit. A conductive elastomer pad 20, or other means to make electrical connection, will act as a bridge from the bottom portions of the pins 34 of the glass header assembly to the circuitry of the electronic device (not shown).

In FIG. 2 a plan view of the glass header assembly is shown after wire bonding is completed but before the unit is hermetically sealed through a cold welding process. The glass header assembly 10 illustrates the locating pins 32A and 32B, the plurality of terminal connecting pins 34, and the associated crystal plate 46 with its wire bonding contact pads 35. Wire bonds 33 are made in customary fashion between the wire bond pads 35 on the crystal 46 and a like number of terminal connecting pins 34. The wire bonds are of an extremely fine wire and are normally formed in a arch as shown, to reduce transmission of vibration to the crystal during operation.

In FIG. 3 a sectional view along lines 3--3 of FIG. 2 is illustrated before the support member 44 has been lowered by the melting of the indium ring 42. The crystal plate 46 rests securely within the recess 45 (not shown) of the support member 44, but without touching the center split mounting post's two independent ground sides 36A and 36B.

In FIG. 4 a sectional view along lines 3--3 of FIG. 2 is illustrated after the support member 44 has been lowered following the melting of the indium ring 42 and after the crystal package assembly 10 has been hermetically sealed by the cold welding process.

This simple construction allows the crystal electrodes on the top surface plate 46 to be wire bonded to the terminal connecting pins 34 without flexing or repositioning the crystal plate once the crystal plate has been placed in the recess cavity contained within the support member 44. The glass header 30 has a extending flange 31 which facilitates the receiving of the overfitting metal cover 50, which is then sealed through the use of cold-welding process.

Thus, there has been provided according to the invention, an improved, simple and inexpensive five spot crystal package which will allow the crystal plate to be adequately supported after initial placement within a retaining support member, allowing wire bonding of the crystal plate electrodes to the terminal pins and hermetically sealing the assembly by a cold welding process. Although the foregoing has been an description and illustration of specific embodiments of the invention, various modification and changes thereto can be made by persons skilled in the art within the scope and spure of the invention as defined by the following claims. 

What is claimed is:
 1. A method of mounting and making electrical wire connections to a multi-electrode crystal wafer, comprising the steps of:providing a base member with an upstanding support post and a plurality of spaced terminal elements and locating pins thereon; placing a ring of conductive material, which is conducive to melting and of a predetermined thickness, on said base member overlying said support post; placing said crystal wafer on a carrier member, having an aperture less than the diameter of said crystal wafer so as to support an edge portion thereof; placing a small amount of conductive paste material to the top surface of said support post; placing said carrier member with said crystal wafer on said base member in a manner keyed to said locating pins and resting on said ring of conductive material whereby the crystal wafer is unsupported by the support post of said base member; making wire bonds from the crystal electrodes to the respective base member terminal elements while the edge of said crystal wafer is fully supported; and temporarily applying downward pressure to the top of said carrier member and raising the ambient temperature to a level to melt the ring of conductive material whereby said carrier moves downwardly and said crystal wafer is fastened and supported solely on said support post.
 2. A method of mounting and making electrical wire connections to a multi-electrode crystal wafer in accordance with claim 1 wherein the ring of conductive material is made from indium.
 3. A method of mounting and making electrical connections to a multi-electrode crystal wafer in accordance with claim 1 wherein a weighting fixture is provided to apply said temporary pressure to the top of said carrier member during melting of said conductor ring.
 4. A method of stationing a crystal plate within a crystal package assembly while facilitating the appropriate electrical connections of the conductive electrode patterns found on each surface of said plate, comprising the steps of:preparing a crystal plate having a plurality of conductive electrode patterns and contact pads on each surface thereof; preparing the header base member having a plurality of locating pins and terminal connecting pins thereon; attaching a mounting post within the glass header base member; placing a small amount of conductive paste material to the top surface of said mounting post; positioning a circular indium ring centrally on the top surface of the glass header base member, so as to encompass the center split mounting post; positioning an elongated support member, with a central recessed area and aperture for accommodating the said crystal plate, on the top surface of the circular indium ring, over the protruding locating pins on the base member; positioning the said crystal plate within the flat recessed area of said elongated support member, said plate being thereby supported around its periphery; making wire bonds from the contact pads on the crystal plate to the correct terminal connecting pins of the header base member; temporarily positioning a weighted fixture on top of the elongated suport member, while heating the entire header base member to the melting point of Indium, resulting in the crystal plate being fastened and supported solely on the mounting post; and hermetically sealing an overfitting protective mating cover to the glass header base member through the use of cold welding apparatus. 